An electron microscopic study of retinal degeneration in Sprague-Dawley rats

Retinal degeneration in untreated, female Sprague-Dawley rats was studied by electron microscopy and horseradish peroxidase tracer technique. The degeneration appeared to have started at a very young age. The severity of the defect varied from a decrease of photoreceptor nuclei to total loss of receptor cells and the pigment epithelium. In mild degeneration some regions of the retinal pigment epithelium became bilayered and the basal plasma membrane became flattened or formed elaborate infoldings. Breaks in Bruch's membrane occurred in severe degeneration. Degeneration of the pigment epithelium allowed permeation of tracer material from the choroid into the retina.     

Development of the crayfish retina: A light and electron microscopic study

The development of the crayfish retina was examined in embryos and first, second and third instars with both and light and electron microscope. Light microscopic observations indicate that differentiation begins at the posterior portion of the optic disc and progresses in an anterior direction. Development of screening pigment, dioptric elements, and rhabdoms all parallel this posterior to anterior gradient in the retina. Tracer studies in early embryos reveal that the retina is separated from the proximal neuropil regions by a distinct vascular space. This observation suggests that the source of new cells for the retina may not be the more proximal cell proliferation zone as previously indicated. It is proposed that mitotic activity within the retina and/or differentiation of cells from the anterior surface layer of the eye may be sources for addition of new cells to the retina. Proto-ommatidial clusters of seven retinula cells occur very early at the posterior region of the embryonic retina. Initially the receptor cells extend throughout the entire thickness of the retina, but later they withdraw from beneath the cornea to occupy only the proximal portion of the retina. Microvilli of the rhabdom arise from the centrally opposed membranes of the retinula cells in each cell cluster. Each new microvillus contains a core of fine filaments which extend out into the cytoplasm at its base. As development of the microvilli continues, the core filaments appear to be lost or altered, but the cytoplasmic bundles at the base of the microvilli persist.     

Scanning electron microscopic study of degeneration and regeneration in the olfactory epithelium after axotomy

Brain Cell Biology - The olfactory epithelium of the adult hamster (Mesocricetus auratus) was examined with the scanning electron microscope following olfactory nerve axotomy. Axotomy results in...     

An electron microscopic study of the human infundibulum

Summary For a limited period during the oogenesis of Protopterus, blebs of the perinuclear cistern contain, in addition to other inclusions, a special kind of microtubular elements. Most of these blebs face parts of multiple nucleolar bodies that extend toward and make contact with the inner nuclear membrane. The microtubular lumen contains a finely dispersed material of moderate electron density which seems to be in contact with this nucleolar material.Aside from these intracisternal structures there are, within both the perinuclear cytoplasm and the nucleoplasm, similar microtubular arrays without apparent connection with the nuclear envelope. These are either enclosed by membranes derived from those of the envelope or unconfined, having escaped through breaks in their respective bounding membranes. Extracisternal tubules are presumed to have passed their period of putative functional activity and to be undergoing a process of regression and subsequent disintegration.Among possible roles attributable to the intracisternal microtubular apparatus are the following: (1) It may serve for the transport of special nucleolar components to the cytoplasm, possibly to be incorporated in the matrix of developing perinuclear mitochondria; (2) it may provide openings in the nuclear membranes for the direct passage of particulate elements between nucleus and cytoplasm; (3) it may be instrumental in the breakdown of parts of the nuclear envelope prior to its restitution during the subsequent phase of oogenesis.Supported by grants NB-00840 and NB-05219 from the U.S.P.H.S.     

An electron microscopic study of the human epidermal keratinocyte

Summary 1. The epidermis of the flexor surface of the upper arm of human subjects was studied with the electron microscope. 2. The cytoplasm of the keratinocytes in the basal layer contained many tonofilaments, ribosomes and other cell organelles. The tonofilaments were arranged singly or in loose bundles and many were attached to the inner membrane of the desmosomes. Along the basal border of the cells pinocytotic vesicles could be seen at different stages of development. 3. The keratinocytes in the stratum spinosum differed from those in the basal layer in two main ways: (a) The tonofilaments were grouped together into large compact bundles known as tonofibrils and it was possible to determine a definite beading or cross banding along the length of some of the filaments. (b) The cells were assuming a flattened shape. 4. The keratinocytes in the stratum granulosum possessed large numbers of irregularly shaped keratohyaline granules. The granules were strongly osmiophilic and were always situated on a meshwork of tonofibrils. The keratohyaline granules had no internal structure. The nuclei and mitochondria showed evidence of degeneration. 5. The keratinocytes in the stratum corneum were long and flattened. The cell walls showed increased electron density and were considerably thickened. The cytoplasm was filled with closely packed fibres separated by a small amount of lucent matrix. The fibres were grouped together in bundles running in different directions within the flattened squames. The fibres had along their entire length alternating areas of high and low electron density. The keratohyalin granules had disappeared and nothing remained of the nuclei or the organelles. In the deepest cells of this region the fibres were sometimes loosely packed leaving large irregular open spaces. This area corresponded to the stratum lucidum. In the most superficial layers of the stratum corneum the fibres appeared to be breaking down so that little remained within the keratinocyte except large lucent spaces. The desmosomes showed distinct structural changes. 6. An attempt was made to correlate the structural changes in the different epidermal layers with the process of keratinization. The possible part that keratohyalin may play in the process of thickening of the cell walls was discussed. The relationship between the desmosome and its dynamic environment was considered.I wish to express my sincere thanks to Dr. David Hilding of the Department of Otolaryngology for the use of an R.C.A. electron microscope and other facilities in his laboratory. This research was supported by the United States Public Health Service and American Cancer Society grants. USPHS CA 04679-07, NB 03995.